Cotton candy preparing device

ABSTRACT

A cotton candy preparing device is provided that has a rotary pot dividable into a pot upper portion and a pot bottom portion, a plurality of legs extending downwards from near a circumferential edge portion of a lower end of the upper pot portion and including a leg end portion expanding outwards at a lower end thereof, a heating plate provided on an upper surface of the pot bottom portion, and leg receiving holes provided near a circumferential edge portion of the upper surface of the pot bottom portion to allow the legs to be inserted individually, and the leg receiving holes each have an inserting portion permitting the passage of the leg end portion and a leg stopping portion connecting continuously to a side of the inserting portion and whose width to an outer circumferential direction of the rotary pot is made narrower than the inserting portion.

CROSS-REFERENCE TO RELATED APPLICATION

This application is based upon and claims the benefit of priority under35 USC 119 of Japanese Patent Application No. 2015-132441 filed on Jul.1, 2015, the entire disclosure of which, including the description,claims, drawings and abstract, is incorporated herein by reference.

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to a device for preparing cotton candies.

Description of the Related Art

In these days, devices have been provided by which a child, togetherwith his or her parent, can prepare cotton candies using granulatedsugar or sugar candy as a material in their house. Then, variousproposals in relation to these cotton candy preparing devices (forexample, Japanese Unexamined Patent Application No. 2002-187 andJapanese Unexamined Patent Application No. 2003-333994) have also beenmade.

The cotton candy preparing device includes a main body portion thatmakes up a base, a rotary mechanism portion and a pan portion thatreceives cotton-like sugar candies. Then, a heater is provided in therotary mechanism portion to heat and melt a material such as sugar orsugar candy loaded in an interior of a rotary pot, and the rotary pot isrotated at high speeds to discharge the material so melted in the formof fine threads of sugar or candy from minute holes or gaps formed onthe circumference of the rotary pot.

As described above, with the cotton candy preparing device, the user canenjoy preparing easily cotton candy by loading granulated sugar or sugarcandy from the upper portion of the rotary mechanism and melting thesugar or the like at high temperatures into the form of fine threads ofsugar.

However, when this cotton candy preparing device is used repeatedly,there occurs from time to time a situation in which liquefied sugar thatis discharged from the rotary pot is not formed into uniform finethreads of sugar, whereby it is not possible to prepare good cottoncandy.

SUMMARY OF THE INVENTION

The present invention provides by eliminating the problem describedabove a cotton candy preparing device that can prepare cotton candy in agood condition at all times by facilitating the cleaning of a rotary poteven in a house.

According to an aspect of the invention, there is provided a cottoncandy preparing device having a rotary pot that can be divided into apot upper portion and a pot bottom portion. A plurality of legs thatextend downwards from the vicinity of a circumferential edge portion ofa lower end of the upper pot portion and which each include a leg endportion that expands outwards at a lower end thereof. A heating platethat is provided on an upper surface of the pot bottom portion and legreceiving holes that are provided near a circumferential edge portion ofthe upper surface of the pot bottom portion and into which the legs canbe inserted individually. The leg receiving holes each have an insertingportion that can permit the passage of the leg end portion and a legstopping portion that connects continuously to a side of the insertingportion and whose width to an outer circumferential direction of therotary pot is made narrower than the inserting portion.

In the cotton candy preparing device, the pot bottom portion has arod-shaped engaging pin below the heating plate, and the engaging pinhas an engaging projecting body that is provided on a side of theengaging pin so as to project into a triangular shape therefrom and isbiased by an elastic body so as cause the engaging projecting body toproject into the leg receiving hole.

In the cotton candy preparing device, the plurality of legs areintegrated with a ring member that can be brought into contact with acircumferential edge of the heating plate, and the legs and the ringmember are formed of a conductive material, and contact detectingmembers are provided in positions on lower surfaces of the leg receivingholes of the pot bottom portion, so that energization is allowed tooccur between the leg end portions and the contact detecting members orbetween the contact detecting members when the leg end portions and thecontact detecting members are brought into contact with each other.

In the cotton candy preparing device according to the invention, therotary pot can be divided into the pot upper portion having the legsthat extend downwards from the lower end thereof and the pot bottomportion having the heating plate on the upper surface thereof. The legreceiving holes are provided in the pot bottom portion into which thelegs can be inserted. The leg receiving holes each has the insertingportion that enables the insertion of the leg into the leg receivingportion and the leg stopping portion that is narrower than the insertingportion and which can prevent the dislocation of the leg end portionthat expands outwards from the leg receiving hole. Thus, the pot upperportion and the pot bottom portion can be integrated with each other foruse by locking the legs of the upper pot portion in the leg receivingholes.

Then, the pot upper portion is separated from the pot bottom portion byremoving the lets and the leg end portions from the inserting portionsby rotating the pot upper portion, thereby making it possible tofacilitate the cleaning of the heating plate that melts granulated sugaror sugar candy, whereby the interior of the rotary pot can be madeclean. Thus, granulated sugar or sugar candy can be melted so well thatthe sugar or the like so melted can be formed into uniform fine threadsof sugar, enabling the preparation of cotton candy for a long period oftime.

In addition, the rod-shaped engaging pin has the engaging projection onthe side thereof which projects into the triangular shape, and thisengaging pin is provided on the pot bottom portion. Then, the engagingpin is biased by the elastic body so that the engaging projection canproject into the leg receiving hole. Thus, in attaching the pot upperportion to the pot bottom portion by inserting the legs into the legreceiving holes, the engaging projection needs to be moved so as to bedislocated from the leg receiving hole against the elastic force of theelastic body.

Consequently, when moving the leg from the inserting portion to the legstopping portion of the leg receiving hole, there is caused a resistanceagainst the rotation of the pot upper portion, however, the rotationresistance is lost or eliminated when the leg is moved to thepredetermined position on the leg stopping portion. Thus, the properfixing of the pot upper portion to the pot bottom portion can bedetermined by feeling that the rotation resistance is lost.

Further, the legs are integrated with the ring member, and the legs andthe ring member are formed of the conductive material. The contactdetecting members are provided in the positions on the lower surfaces ofthe leg receiving holes, whereby the energization between the contactdetecting members is enabled via the ring member. Thus, the attachmentof the ring member, that is, the pot upper portion to the pot bottomportion can be confirmed electrically.

Thus, the operation of the cotton candy preparing device including theoperation of the rotary pot or the like can electrically be controlledwith ease when the pot upper portion is not attached to the pot bottomportion.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 is a perspective view showing a cotton candy preparing deviceaccording to an embodiment of the invention and a power supply adaptor.

FIG. 2 is a half sectional perspective view of the cotton candypreparing device according to the embodiment of the invention.

FIG. 3 is a half sectional view of the cotton candy preparing deviceaccording to the embodiment of the invention.

FIG. 4 is a bottom perspective view showing a pan portion of the cottoncandy preparing device according to the embodiment of the invention.

FIG. 5 is a half sectional view of the pan portion of the cotton candypreparing device according to the embodiment of the invention.

FIG. 6 is a perspective view showing a state in which the pan portion isremoved from the cotton candy preparing device according to theembodiment of the invention.

FIG. 7 is a perspective view showing an interior of a main body portionand a rotary mechanism portion of the cotton candy preparing deviceaccording to the embodiment of the invention.

FIG. 8 is an exploded perspective view showing a main body cover portionof the cotton candy preparing device according to the embodiment of theinvention.

FIG. 9 is a sectional view of a pot upper portion of the rotary pot ofthe cotton candy preparing device according to the embodiment of theinvention.

FIG. 10 is a perspective view of the pot upper portion of the rotary potof the cotton candy preparing device according to the embodiment of theinvention.

FIG. 11 is a side view of the pot upper portion of the rotary pot of thecotton candy preparing device according to the embodiment of theinvention.

FIG. 12 is a bottom view of the pot upper portion of the rotary pot ofthe cotton candy preparing device according to the embodiment of theinvention.

FIG. 13 is a top view of the cotton candy preparing device according tothe embodiment of the invention with the pot upper portion and the mainbody cover portion removed therefrom.

FIG. 14 is an exploded perspective view of the rotary pot of the cottoncandy preparing device according to the embodiment of the invention.

FIG. 15 is a top view showing an upper surface of a pot bottom main bodyof the cotton candy preparing device according to the embodiment of theinvention.

FIG. 16 is a bottom view showing a lower surface of the pot bottom mainbody of the cotton candy preparing device according to the embodiment ofthe invention.

FIG. 17 is a perspective view of the pot bottom portion and the mainbody bottom portion of the cotton candy preparing device according tothe embodiment of the invention showing connecting circuitries thereof.

FIG. 18 is an exploded perspective view showing the construction of apower supply switch of the cotton candy preparing device according tothe embodiment of the invention.

FIG. 19 is a circuit diagram showing an electric circuit configurationof the cotton candy preparing device according to the embodiment of theinvention.

FIG. 20 is a flowchart showing operating states of the cotton candypreparing device according to the embodiment of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

As shown in FIG. 1, an embodiment of a cotton candy preparing deviceaccording to the invention is used in combination with a power supplyadaptor 480 by a child and his or her parent in their house.

As shown in FIGS. 1 to 3, this cotton candy preparing device has a trayor pan portion 201 disposed above a main body portion 110 and a rotarypot 260, functioning as a rotary mechanism unit 250, that is disposedinside the pan portion 201.

In addition, the main body portion 110 is formed by a main body bottomportion 141 and a main body cover portion 111 and accommodates in aninterior thereof a driving motor that rotates the rotary pot 260 and acontrol circuit board.

The rotary mechanism unit 250 is provided at a center of the main bodyportion 110, and a pot upper portion 261 of the rotary pot 260 thatmakes up a main part of the rotary mechanism unit 250 is surrounded bythe pan portion 201 so that the pot upper portion 261 is accommodated inan interior of the pan portion 201 while being allowed to projectupwards of the main body portion 110 from a center of the main bodycover portion 111.

As shown in FIGS. 4 and 5, this pan portion 201 is a combination of anupper pan 203 and a lower pan 211.

The upper pan 203 has a cover portion 205 that has an opening portion207 that is opened largely in a center thereof, so that cotton-likecandies that are prepared along the circumference of the rotary pot 206in the interior of the pan portion 201 can get tangled up on a distalend of a stick that is inserted from the opening portion 207 into theinterior of the pan portion 201.

The lower pan 211 has a cylindrical side barrel portion 213 that definesan outer circumferential wall of the pan portion 201 and supports anouter circumferential edge of the cover portion 205 at an upper end ofthe side barrel portion 213. Then, the lower pan 211 has a plate-likeannular bottom portion 215 having a ring-like shape at a lower end ofthe side barrel portion 213. Thus, the lower pan 211 accommodates therotary pot 260 in an interior of the side barrel portion 213.

Further, the lower pan 211 includes an inner cylindrical portion 217having a cylindrical shape that is provided therein so as to riseupwards from an inner edge of the annular bottom portion 215 and isfixedly fitted on a holding cylindrical portion 117 of the main bodyportion 110, which will be described later, at the inner tube portion217 so as to cover circumferentially a pot bottom portion 310 of therotary pot 260.

In addition, the lower pan 211 has a locking cylinder 221 having acylindrical shape that is provided at a portion on a lower surface ofthe annular bottom portion 215 that lies near an inner circumferentialedge portion of the annular bottom portion 215 so as to slightly projectdownwards therefrom. This locking cylinder 221 has plate-like lockingpieces 223 that are provided at two diametrically facing locationsthereon so as to project radially inwards from an inner wall at a lowerend of the locking cylinder 221. Thus, by adopting this configuration,when mounting the pan portion 201 on the main body portion 110, the panportion 201 can be fixed to the main body portion 110 at a predeterminedposition.

The main body portion 110 on which the pan portion 201 is mounteddefines a space therein by the main body bottom portion 141 and the mainbody cover portion 111 and accommodates therein the rotary mechanismunit 250 that includes a drive unit made up of a motor 253 and a motorgear 255 and the rotary pot 260 that is driven to rotate by the driveunit 251.

Then, as shown in FIG. 6, the main body portion 110 accommodates therotary mechanism unit 250 in such a way that the pot upper portion 261of the rotary pot 260 projects from an upper end of a holding cylinderof the main body portion 110 that is formed by the main body coverportion 111 and the main body bottom portion 141.

As shown in FIGS. 6, 7 and 8, the main body cover portion 111 has a flatand annular upper surface portion 115 that extends radially inwards froman upper end of a substantially short cylindrical upper outer edgeportion 113 and the holding cylindrical portion 117 having a cylindricalshape that extends upwards from a central inner edge of the uppersurface portion 115.

An auxiliary ring 131 and a protection ring 133 are provided at an upperend of the holding cylindrical portion 117. The auxiliary ring 131projects radially inwards from the upper end of the holding cylindricalportion 117.

The auxiliary ring 131 is made up of two semicircular portions. Eachsemicircular portion includes a circumferential edge portion 131 a thatis fixed to the upper end of the holding cylindrical portion 117 and aplate-like semi-annular projecting ring 131 b that projects radiallyinwards from an upper end of the circumferential edge portion 131 a insuch a way that an inner edge is situated near a lower end of an outercircumference of a pot bottom main body 323, which will be describedlater.

The projection ring 133 includes a circumferential edge ring 133 a thatcovers the circumferential portions 131 a of the auxiliary ring 133 andis fixed to the holding cylindrical portion 117. The projecting ring 133has a protecting portion 133 b that is directed upwards and radiallyinwards from an upper end of the circumferential ring 133 a. An innercircumferential edge of the protecting portion 133 b is situated near anupper end of an outer circumference of the pot bottom main body 323,which will be described later, so that a gap between the rotary pot 260that projects from the holding cylindrical portion 117 of the main bodycover portion 111 to rotate and the holding cylindrical portion 117 ofthe main body cover portion 111 is narrowed to thereby prevent theintrusion of foreign matters into an interior of the main body portion110 in a falling fashion.

The main body cover portion 111 has a step portion 121 formed around alower end circumference of the holding cylindrical portion 117, and aninner circumferential edge of the annular bottom portion 215 of thelower pan 211 can be supported on an upper surface of the step portion121. Substantially rectangular engaging pieces 123 are providedindividually at two locations on a circumference of the step portion soas to extend radially outwards therefrom in the same height as that ofthe upper surface of the step portion 121.

These two engaging pieces 123 are provided in diametrically facingpositions on the step portion 121 that is formed into an annular shapeon the upper surface 115 of the main body cover portion 111. A distancebetween outer end portions of both the engaging pieces 123 issubstantially equal to a bore diameter of the locking cylinder 221 ofthe lower pan 211, so that the engaging pieces 123 can be accommodatedinside the locking cylinder 221.

A gap having a height substantially equal to a thickness of the lockingpiece 223 is formed between a lower surface of the engaging piece 123and an upper surface of the main body cover portion 111, so that thelocking piece 223 can be accommodated under the engaging piece 123.

Further, an engaging opening portion 125 having a shape that matchessubstantially the shape of the engaging piece 123 is formed on the uppersurface portion 115 in a position lying below the engaging piece 123.Then, the locking pieces 223 that are provided on the locking cylinder221 of the lower pan 211 individually have lower surfaces that areprotuberant slightly downwards at centers thereof. Thus, when thelocking pieces 223 of the pan portion 201 are located to lie below thecorresponding engaging pieces 123 of the main body cover portion 111,the lower surfaces of the locking pieces 223 that are slightlyprotuberant at the centers thereof fit in the engaging opening portions125, whereby the rotation resistance of the pan portion 201 is lost,thereby allowing the user or operator to determine on a proper fixingposition of the pan portion 201 to the main body portion 110.

The engaging piece 123 shown in FIG. 8 has a locking wall 123 a at oneside of the engaging piece 123 projecting from the step portion 121which follows a circumference of the holding cylindrical portion 117, sothat the locking pieces 223 can be inserted under the engaging pieces123 only from one direction when the pan portion 201 is placed on themain body portion 110 by placing the inner cylindrical portion 217 ofthe pan portion 201 on the holding cylindrical portion 117 so that theannular bottom portion 215 is brought into contact with the uppersurface of the step portion 121 and the pan portion 201 is rotated in ahorizontal direction relative to the main body portion 110.

An operating projection 451 of a locking body 441 of a power supplyswitch 410, which will be described later, is located in one of theengaging opening portions 125, and when the locking piece 223 isinserted under the engaging pieces 123, the locking piece 223 moves theoperating projection 451 in the direction of the center of the main bodyportion 110 in an interior of the engaging opening portion 125.

Further, a power supply terminal hole 137 into which an adaptor pin 481of the power supply adaptor 480 is inserted and a switch hole throughwhich a switch knob 423 of the power supply switch 410 is allowed toproject from the main body portion 110 are provided in the upper outeredge portion 113 of the main body cover portion 111.

As shown in FIG. 7, the power supply terminal hole 137 is provided at alower end of the upper outer edge portion 113 so that an upper half of afront surface of an adaptor jack 485 can bite into the upper outer edgeportion 113 of the main body cover portion 111. The switch hole 135 isalso provided at the lower end of the upper outer edge portion 113 sothat an upper half of the switch knob 423 of a switch operating rod 411can bite into the upper outer edge portion 113 of the main body coverportion 111.

The main body bottom portion 141 of the main body portion 110 has abottom plate portion 143 having a circular disc shape and a lower outeredge portion 145 having a cylindrical shape that rises from acircumferential edge of the bottom plate portion 143. An upper end ofthe lower outer edge portion 145 is joined to the lower end of the upperouter edge portion 113 of the main body cover portion 111 to make up themain body portion 110 in which an interior space is defined by the mainbody bottom portion 141 and the main body cover portion 111.

As shown in FIG. 3, the main body bottom portion 141 includes feet 153on a lower surface of the bottom plate portion 143 so as to define aspace between the bottom plate portion 143 and a table surface on whichthe cotton candy preparing device 100 is rested. In addition, aplurality of outside air intake holes 151 are provided in the bottomplate portion 143.

Then, the main body bottom portion 141 has a pot mounting base portion161 that is provided substantially at a center of the bottom plateportion 143, and the rotary mechanism unit 250 made up of the drive unit251 including the motor 253 that drives the rotary pot 260 to rotate andthe rotary pot 260 is fixedly accommodated in the main body bottomportion 141.

As shown in FIGS. 2 and 3, a motor fixing portion 163 and a shaftholding portion 165 are provided in an interior of the pot mounting baseportion 161. The driving motor 253 is fixedly accommodated in theinterior of the pot mounting base portion 161, and a lower end of arotation shaft 397 of the rotary pot 260 is held by the shaft holdingportion 165.

Further, the rotation shaft 397 is held on an upper side thereby by abearing plate 167 that is disposed above the pot mounting base portion161. Then, the rotary pot 260 which is formed by the pot bottom portion310 that is disposed on the bearing shaft 167 and the pot upper portion261 is supported rotatably by the rotation shaft 397.

In addition, the control circuit board 175 and the power supply switch410 are provide on an upper surface of the bottom plate portion 143 at aportion lying on a side of the pot mounting base portion 161.

Electronic components such as a control IC 535 that controls the motor253 and a heater 315 of the cotton candy preparing device 100, aresistance and a capacitor are mounted on the control circuit board 175.Additionally, a connecting plug 547 into which a connecting jack 545 ofa cord that is connected to the motor 253 is inserted is also fixed onto the control circuit board 175.

The pot upper portion 261 of the rotary pot 260 that projects upwardsfrom the holding cylindrical portion 117 of the main body cover portion111 shown in FIG. 6 has a protuberant portion 275 having an extendeddiameter at a lower end of a cylindrical outer wall portion 263 and acylindrical skirt portion 277 that extends downwards from an outer edgeof the protuberant portion 275 as shown in FIGS. 9 and 10.

The pot upper portion 261 has a top portion 265 that projects radiallyinwards into an annular shape from an upper end of the outer wallportion 263 and a depression that is formed at a center of the topportion 265 as a semi-spherical loading port that is defined by aloading wall 267 and an opening and closing member 271.

This opening and closing member 271 has a shape that is substantially ahalf of a semi-spherical shape and has a knob portion 273 that projectsradially outwards from an upper end portion thereof. When the knobportion 273 is rotated in such way as to be moved upwards, an openingportion is formed between the loading wall 267 and the opening andclosing member 271, so that granulated sugar or sugar candy that isloaded into the semi-spherical depression defined by the loading wall267 and the opening and closing member 271 and functioning as theloading port is allowed to fall into the interior of the rotary pot 260through the opening portion.

As shown in FIG. 6 and other figures, the opening and closing member 271normally forms the semi-spherical depression by the opening and closingmember 271 and the loading wall 267 with an upper surface of the knobportion 273 positioned so as to be level with an upper surface of thetop portion 267 without producing a gap between the opening and closingmember 271 and the loading wall 267.

The pot upper portion 261 has in the interior thereof an upper innerwall 281 and a lower inner wall 283 which are both an cylindrical innerwall, so that granulated sugar or sugar candy that falls from the gapproduced as a result of the rotation of the opening and closing member271 is allowed to fall on a heating plate 311 that is provided on anupper end face of the pot bottom portion 310.

The pot upper portion 261 has a diametrically expanded inclined portion285 having a conically annular shape in which a lower diameter isgradually expanded so that the lower diameter becomes greater than anupper diameter and an annular projecting portion 293 having a flatannular shape that extends radially outwards in a horizontal directionfrom a lower end of the diametrically expanded inclined portion 285.

Further, the pot upper portion 261 has a circumferential portion 291having a lower surface that is slightly higher than a lower surface ofthe annular projecting portion 293, and an outer edge of thecircumferential portion 291 is joined to a lower end of the skirtportion 277.

Then, the pot upper portion 261 has a ring member 301 on the lowersurface of the annular projecting portion 293, and this ring member 301has a flat annular shape and is made of a metallic conductive material.

As shown in FIGS. 9 and 12, a plurality of plate-like ribs 287 areprovided in the diametrically expanded inclined portion 285 so as toproject inwards from the diametrically expanded inclined portion 285.

These ribs 287 have such a height that lower ends thereof are level witha lower surface of the ring member 301 or are slightly higher than thelower surface of the ring member 301. Then, by doing so, when the lowersurface of the ring member 301 is in contact with the upper surface ofthe heating plate 311, the lower ends of the ribs 287 are also incontact with the upper surface of the heating plate 311 or a slight gapcan be defined between the lower ends of the ribs 287 and the uppersurface of the heating plate 311.

Consequently, when sugar candy that falls into the interior of thecylindrical lower inner wall 283 remains in a solid state until they aremelted on the heating plate 311, the sugar candy can be prevented frommoving from the center of the heating plate 311 to the periphery of theheating plate 311 as a result of the rotation of the rotary pot 260.

Then, six depressed portions 295 are provided at equal intervals on thelower surface of the annular projecting portion 293, and these depressedportions 295 are situated slightly higher than the lower surface of theannular projecting portion 293 having the cylindrical shape (refer toFIG. 14).

The depressed portions 295 each have an identical fan shape and areopened to an outer edge of the annular projecting portion 293. Thedepressed portions 295 are each formed so as to have a radial width thatextends towards the center of the pot upper portion 261 from the outeredge of the annular projecting portion 293 to a radially middle portionof the lower surface of the annular projecting portion 293.

The ring member 301 is the annular metallic flat plate and has anoutside diameter that substantially coincides with an outside diameterof the annular projecting portion 293 and a bore diameter thatsubstantially coincides with a bore diameter of the annular projectingportion 293. The bore diameter of the ring member 301 is smaller than adiameter of the heating plate 311 so that at least an inner edge portionof the ring member 301 or, preferably, a portion of the ring member 301that extends from an inner edge to the vicinity of an outer edge of thering member 301 can overlap the heating plate 311 so as to be broughtinto contact therewith.

Further, the ring member 301 has six first expanded portions 303 thatare provided at equal intervals therein by cutting correspondingportions of the ring member 301 into the same shape from an inner edgeof the ring member 301. Each first expanded portion 303 has a secondexpanded portion 305 that is formed by cutting corresponding portions ofthe ring member 301 further radially outwards at a center of acircumferential width of the first expanded portion 303.

Then, a diameter of a circle that connects outer edges of the six firstexpanded portions 303 is smaller than a diameter of a circle thatconnects inner edges of the depressed portions 295 that are formed onthe annular projecting portion 293. The circumferential width of eachfirst expanded portion 303 is the same as or slightly wider than acircumferential width of each depressed portion 295.

The second expanded portions 305 that are cut further radially outwardsthan the first expanded portions 303 from substantially thecircumferential centers of the first expanded portions 303 are formed sothat a diameter of a circle that connects outer edges of the secondexpanded portions 305 is slightly larger than the diameter of the circlethat connects the inner edges of the depressed portions 295 and that acircumferential width of each second expanded portion 305 is narrowerthan the circumferential width of each depressed portion 295.

Consequently, in an interior space of the pot upper portion 261 of therotary pot 260, a circumferential width is narrowed by the firstexpanded portions 303, and the circumferential width is narrowed furtherby the second expanded portions 305. Then, the interior space of the potupper portion 261 is connected continuously with the depressed portions295 via slight gaps at outer end portions of the second expandedportions 305. Then, since the circumferential widths of the depressedportions 295 are wider than the circumferential widths of the secondexpanded portions 305, the interior space of the pot upper portion 261is connected continuously with an exterior portion lying outside anouter circumference of the rotary pot 260.

By adopting this configuration, when sugar or sugar candy that is loadedfrom the upper portion into the interior of the rotary port 260 isheated to be melted, the melt is fed into the first expanded portions303 by means of a centrifugal force between the heating plate 311 andthe annular projecting portion 293 and is fed further into the secondexpanded portions 305, whereby the melt is discharged to the exteriorportion of the rotary pot 260 from the gaps defined by the depressedportions 295 between the ring member 301 and the annular projectingportion 293. Since the heating plate 311 and the ring member 301 areboth heated to high temperatures, even sugar candy can be melted in anensured fashion, whereby granulated sugar and sugar candy can be madewell into cotton-like conditions.

Namely, a material of a large size such as sugar candy is held long atthe center where a working centrifugal force is small by the ribs 287and reaches the inner edge position of the ring member 301 through thegaps defined between the ribs 287 when it is melted. On the other hand,a material of a small size and easy to be melted such as granulatedsugar is quick to reach the inner edge position of the ring member 301through the gaps defined between the ribs 287.

Then, the melted material that has reached the inner edge position ofthe ring member 301 reaches outer circumferential end portions of thesecond expanded portions 305 through the first expanded portions 303whose circumferential width is gradually narrowed.

Further, the melted material is lifted up from the outer circumferentialend portions of the second expanded portions 305 to the gaps above thering member 301 and is then discharged to the exterior portiontherefrom. Thus, the material is heated by the heating plate 311 and thering member 301 while being subjected to moving resistance sequentially,and therefore, the material is melted so sufficiently in an ensuredfashion that the material is formed into a uniform thin thread-likeshape.

The ring member 301 has three legs 307 that extends perpendicularlydownwards from an outer circumferential edge thereof. Lower ends of thelegs 307 are extended to project radially outwards into leg end portions309, whereby the pot upper portion 261 is attached to the pot bottomportion 310 by these legs 307 and can be fixed to the pot bottom portion310 by the leg end portions 309.

The pot bottom portion 310 has the circular disc-shaped heating plate311 at the center of the upper end thereof as shown in FIG. 13 andincludes, as shown in FIG. 14, a first electrode plate 317, a secondelectrode plate 319, a heater holding plate 313 that holds a pluralityof heaters 315, a heater accommodation plate 321 that accommodates thetwo electrode plates 317, 319 and the heater holding plate 313, a potbottom main body 323 that accommodates the heater accommodation plate321 and the heating plate 311, and a geared plate 373 that is fixed to alower surface of the pot bottom main body 323.

This pot bottom main body 323 has a main body circumferential wall 327that rises into a cylindrical shape from a circumference of a circulardisc-shaped main body plate 325 and a flat plate-like annular portion329 having an annular shape that is provided at an upper end of the mainbody circumferential wall 327 so as to extend radially outwards. Acylindrical outer circumferential wall 331 is provided which extendsperpendicularly downwards from a lower end of an outer edge of theannular portion 329, and a lower end of the outer circumferential wall331 is positioned at substantially the same height as a lower surface ofthe main body plate 325.

The heater accommodation plate 321 and the heating plate 311 areaccommodated on an upper surface of the main body plate 325 and insidethe main body circumferential wall 327, and the second electrode plate319, the heater holding plate 313 and the first electrode plate 317 areaccommodated inside the heater accommodation plate 321.

The heaters 315 that are fixed to the heater accommodation plate 321 arerectangular flat plate-like PTC heaters. Lower surfaces of the heaters315 are brought into close contact with the circular disc-shaped secondelectrode plate 319, while upper surfaces of the heaters 315 are broughtinto close contact with the circular disc-shaped first electrode plate317, whereby a voltage can be applied to the heaters 315 by the firstelectrode plate 317 and the second electrode plate 319.

When the voltage is applied to the heaters 315, the heaters 315 areheated to temperatures ranging substantially from 70° C. to 80° C. Sincethe plurality of PTC heaters are fixedly disposed underneath the heatingplate 311 by means of the heater accommodation plate 321, a wide rangeof the heating plate 311 can be heated uniformly and effectively.

Further, although the plurality of PTC heaters are used, since the PTCheaters are flat and are energized through contact of the upper surfacesand lower surfaces with the corresponding circular disc-shaped electrodeplates, wiring to the PTC heaters can be made simple, thereby making itpossible to energize the PTC heaters easily and in an ensured fashion.

The heating plate 311 is accommodated in the pot bottom main body 323together with the heater accommodation plate 321 in such a way as to beclosely attached to an upper side of the first electrode plate 317 so asto be heated by the heaters 315. An upper surface of a circumferentialedge portion of the heating plate 311 can be closely attached to thering member 301 of the pot upper portion 261.

In this way, in the cotton candy preparing device 100 of the invention,the heater temperature and hence the temperatures of the heating plate311 and the ring member 301 that is in contact with the heating plate311 can be maintained constant by the properties of the heaters by usingthe PTC heaters for the heaters 315.

Consequently, the temperatures of the heaters 315 can be maintainedconstant by supplying a constant voltage to the heaters 315 withoutperforming operations of detecting and controlling the temperatures ofthe heaters 315, thereby making it possible to use the cotton candypreparing device 100 safely in a house.

The pot bottom main body 323 has three leg receiving holes 333 that areprovided at equal intervals on an inner edge of the annular portion 329.Each leg receiving hole 333 has an inserting portion 334 that is sosized as to allow the passage of the leg end portion 309 and a legstopping portion 335 that is provided on a side of the inserting portion334. This leg stopping portion 335 has a radial width that is smallerthan that of the inserting portion 334 so as not to allow the passage ofthe leg end portion 309 while allowing the passage of the leg 307.

An engaging pin 341 and an operating pin 351 are provided below theheater accommodation plate 321 and on an upper surface of the main bodyplate 325 as shown in FIG. 15.

The engaging pin 341 has a rod-like shape is positioned on a lower sideof the annular portion 329 at one end thereof, and this pin end portion343 is attached to the pot bottom body 323 in an oscillating fashion bya screw that functions as a rotation shaft 347 as shown in FIG. 16.

Then, the engaging pin 341 has a triangular engaging projecting body 345that projects partially into the leg receiving hole 333 from a side ofthe rod-shaped main body, so that an opposite end portion to the pin endportion 343 that is attached to the pot bottom main body 323 with therotation shaft 347 can be brought into engagement with the operating pin351.

This operating pin 351 has a rod-like shape and is attached to the uppersurface of the main body plate 325 so as to slide towards the center ofthe pot bottom main body 323 while a center axis thereof is directed tothe center of the pot bottom main body 323 and an outer end portionthereof projects slightly further radially outwards than the annularportion 329 as an operating portion 353.

Then, a lower surface of the operating pin 351 can be brought intoengagement with the end portion of the engaging pin 341, and the endportion of the engaging pin 341 is biased outwards by an elastic body355. The operating portion 353, which is the end portion of theoperating pin 351, is kept projecting slightly from the annular portion329.

When the operating portion 353, which is the end portion of theoperating pin 51, is pushed inwards of the pot bottom main body 323, theend portion of the engaging pin 343 that is in engagement with theoperating pin 351 can be moved inwards so as to rotate the whole of theengaging pin 341 about the pin end portion 343 of the engaging pin 341that is fixed by the rotation shaft 347.

Consequently, when the leg 307 that projects downwards from the lowerend of the pot upper portion 261 is inserted into the leg receiving hole333 of the pot bottom main body 323 and the pot upper portion 261 isrotated, the leg 307 moves from the inserting portion 334 to the legstopping portion 335 of the leg receiving hole 333 to thereby push theengaging projecting body 345 that projects partially into the legreceiving hole 333 towards the center of the pot bottom main body 323,whereby the engaging pin 341 is rotated inwards of the pot bottom mainbody 323 about the rotation shaft 347, compressing the elastic body 355.

Then, when the pot upper portion 261 is rotated so as to move the leg307 to a predetermined position in the leg stopping portion 335, part ofthe engaging projecting body 345 is allowed to project into the legstopping portion 335 of the leg receiving hole 333 as shown in FIG. 15,whereby the leg 307 can be prevented from being dislocated from the legstopping portion 335, and hence, the pot upper portion 261 can beprevented from being dislocated from the pot bottom portion 310.

Since the engaging pin 341 is rotated against the elastic force of theelastic body 355 when the pot upper portion 261 is rotated so as to movethe leg 307 to the predetermined position in the leg stopping portion335, resistance is generated against the rotation of the pot upperportion 261. Then, when the leg 307 reaches the predetermined position,the resisting force applied through the engaging pin 341 by the elasticbody 355 is lost, whereby the fact that the pot upper portion 261 isattached to a predetermined position can be felt through a hand thatfeels a resistance-free sensation.

When removing the pot upper portion 261 from the pot bottom portion 310,the end portion of the engaging pin 343 that is in engagement with theoperating pin 351 is moved towards the center of the pot bottom mainbody 323 by pushing the operating portion 353 inwards of the pot bottomportion 310. This moves the engaging projecting body 345 inwards of thepot bottom main body 323, whereby the engaging projecting body 345 canbe moved inwards of the leg receiving hole 333.

Consequently, the pot upper portion 261 can be rotated so that the leg307 is moved from the leg stopping portion 335 to the inserting portion334 so that the leg 307 and the leg end portion 309 can be removed fromthe inserting portion 334, whereby the pot upper portion 261 can beremoved from the pot bottom portion 310.

As shown in FIG. 16, contact detecting members 361, which are metallicplates, are provided on lower sides of the leg receiving holes 333 inpositions where the leg stopping portions 335 exist, so that the leg endportions 309 and hence the ring member 301 can be energized as a resultof the contact detecting members 361 bring brought into contact with theleg end portions 309.

Then, a gear wheel portion 371 that is fixed to the lower surface of thepot bottom main body 323 has a flat circular gear wheel plate 373 and acylindrical outer circumferential wall 375 that extends perpendicularlydownwards from an outer circumference of the gear wheel plate 373 andalso has a toothed portion 377 on an outer circumferential surface of alower end of the outer circumferential wall 375.

An outside diameter of the outer circumferential wall 375 is slightlysmaller an outside diameter of the main body circumferential wall 327.The toothed portion 377 of the gear wheel portion 371 is brought intomeshing engagement with a motor gear 255 that is fixed to a motor shaftof the motor 253, whereby the pot bottom portion 310 and the pot upperportion 261 are rotated by the motor 253 of the drive unit 251.

As shown in FIG. 17, a shaft fixing hole 379 is provided at a center ofa lower surface of the gear wheel plate 373. Additionally, two contactsof a first contact 381 and a first auxiliary contact 386 are provided inpositions lying equidistant from and diagonal with respect to the centerof the gear wheel plate 373.

In addition, two contacts of a second contact 382 and a second auxiliarycontact 387 are also provided on the lower surface of the gear wheelplate 373 in positions lying equidistant from and diagonal with respectto the center of the gear wheel plate 373, however, the distance fromthe center to the second contact 382 differs from the distance from thecenter to the first contact 381. Further, two contacts of a thirdcontact 383 and a third auxiliary contact 388 are also provided on thelower surface of the gear wheel plate 373 in positions lying equidistantfrom and diagonal with respect to the center of the gear wheel plate373, however, the distance from the center to the third contact 383differs from the distances from the center to the first contact 381 andto the second contact 382.

The first contact 381 to the third contact 383 and the first auxiliarycontact 386 to the third auxiliary contact 388 are each made of aconductive metallic plate. One end of the rectangular metallic plate isfixed to the lower surface of the gear wheel plate 373, and the otherend of the rectangular metallic plate is made into a sliding contactportion that can be pressed against an object surface by means of anelastic force of the metallic plate.

Then, a first electrode ring 171 that can be brought into contact withthe first contact 381 and the first auxiliary contact 386 is fixed to anupper surface of the bearing plate 167 that faces the gear wheel plate373 in parallel. A second electrode ring 172 that can be brought intocontact with the second contact 382 and the second auxiliary contact 387is fixed to the upper surface of the bearing plate 167. A thirdelectrode ring 173 that can be brought into contact with the thirdcontact 383 and the third auxiliary contact 388 is also fixed to theupper surface of the bearing plate 167.

The bearing plate 167 supports rotatably the rotation shaft 397 at thecenter of the first electrode ring 171, the second electrode ring 172and the third electrode ring 173 that are disposed concentrically on theupper surface thereof and has a motor shaft hole 168 in an appropriateposition radially outwards of the first electrode ring 171 to therebysupport rotatably the rotation shaft of the motor 253.

A first lead portion 391 that connects the first contact 381 and thefirst auxiliary contact 386 together, a second lead portion 392 thatconnects the second contact 382 and the second auxiliary contact 387 anda third lead portion that connects the third contact 383 and the thirdauxiliary contact 388 together are provided on the lower surface of thegear wheel plate 373.

In the interior of the pot bottom portion 310, the first lead portion391 is connected to the first electrode plate 317 and one of the threecontact detection members 361, the second lead portion 392 is connectedto the other two contact detection members of the three contactdetection members 361, and the third lead portion 393 is connected tothe second electrode plate 319.

Consequently, electric power that is applied from the first electrodering 171 to the rotary pot 260 by the first lead portion 391 via thefirst contact 381 and the first auxiliary contact 386 is supplied to thefirst electrode plate 317 and is returned to the third lead portion 393from the second electrode plate 319 via the heaters 315 to thereby bereturned to the third electrode ring 173.

Additionally, since the first lead portion 391 is connected to one ofthe three contact detection members, electric power that the first leadportion 391 receives when the contact detection members 361 are incontact with the corresponding leg end portions 309 of the ring member301 is conducted to the other contact detection members 361 via the ringmember 301, is then returned to the second lead portion 392 and isfinally returned to the second electrode ring 172.

Since the two electrodes of the first contact 381 and the firstauxiliary contact 386 are brought into contact with the first electrodering 171 in the way described above, even though the contacts move athigh speeds over the upper surface of the first electrode ring 171 as aresult of the rotation of the rotary pot 260 to thereby be caused tomove away from the electrode ring 171 momentarily, there should no suchsituation that the two contact move away from the electrode ring 171 atthe same time, the energization of the rotary pot 260 from the main bodyportion 110 can be kept executed without any momentary interruption.

Similarly, since the second contact 382 and the second auxiliary contact387 are brought into contact with the second electrode ring 172 and thethird contact 383 and the third auxiliary contact 388 are brought intocontact with the third electrode ring 173, electric power can besupplied to the rotary pot 260 from the main body portion 110 such asthe pot mounting base portion 161, which is the fixing portion, and thebearing plate 167 in an ensured fashion.

Since the two contacts that are brought into contact with each electrodering are disposed in the opposite positions across the center of thegear wheel plate 373, the two contacts can be prevented from moving awayfrom the electrode ring at the same time, thereby making it possible tomaintain the energization of the electrode ring with the lead portion inan ensured fashion.

In addition, since the electrode rings are provided on the upper surfaceof the bearing plate 167 and the contacts that are brought into contactwith the electrode rings are provided on the lower surface of the gearwheel portion 371 that faces the bearing plate 167, compared with a casewhere electric power is supplied to the rotary portion by providing theelectrode rings on the circumference of the rotation shaft 397, an axiallength of the rotation shaft 397 is shortened, whereby the rotary pot260 can be disposed in a low position lying close to the main bodybottom portion 141.

Then, as shown in FIG. 18, the power supply switch 410 of the cottoncandy preparing device 100 is formed by a switch main body 461 thatcontrols the energization of the rotary pot 260, the switch operatingrod 411 that enables the operation of an operating switch 465 of theswitch main body 461 and the locking body 441 that restricts the slidingoperation of the switch operating rod 411.

This switch operating rod 411 has a rod main body 413 that is arod-shaped plate, and a first sliding hole 415 and a second sliding hole417, which are both elongated holes, are provided individually near endsof the rod main body 413.

Inserting shafts 475 that are distal ends of rod receiving shafts 471that are provided on the bottom plate portion 143 of the main bodybottom portion 141 so as to rise therefrom are inserted into the firstsliding hole 415 and the second sliding hole 417, and the switchoperating rod 411 is supported by rod receiving portions 473 formed atupper ends of the rod receiving shafts 471, enabling the rod main body413 of the switch operating rod 411 to slide in an axial direction.

Namely, the rod receiving shafts 471 are rod-like bodies whose upperends are formed into the rod receiving portions 473 and having adiameter that is greater than minor diameters of the first sliding hole415 and the second sliding hole 417. The inserting shafts 475 whosediameters are substantially equal to the minor diameters of the firstsliding hole 415 and the second sliding hole 417 are provided at thedistal ends of the rod receiving shafts 471 so as to extend from theupper ends thereof so that the rod receiving shafts 471 can move inlongitudinal directions of the first sliding hole 415 and the secondsliding hole 417 that are elongated holes, whereby the switch operatingrod 411 can move in the major diameter directions of the first slidinghole 415 and the second sliding hole 417 that are the elongated holes.

In addition, the switch operating rod 411 has a projecting portion 421that extends sideways from the vicinity of the first sliding hole 415 ofthe rod main body 413, and a switch knob 432 is provided at a distal endof the projecting portion 421. This switch knob 423 is positioned in theswitch hole 135 that is formed in the upper outer edge portion 113 ofthe main body cover portion 111 and the lower outer edge portion 145 ofthe main body bottom portion 141, whereby the switch knob 423 can movein a horizontal direction by a finger tip so as to move the switchoperating rod 411 in the axial direction.

The switch operating rod 411 has a locking projection 425 that isprovided on the side surface where the projecting portion 421 of the rodmain body 413 is provided in a position lying closer to the secondsliding hole 417 than a center of the rod main body 413 so as to projectupwards therefrom and an abutting projection 427 that is provided on anupper surface of the rod main body 413 in a position lying near theposition where the projecting portion 421 is provided and near a centralline position of the rod main body 413 so as to project upwardstherefrom.

Further, the switch operating rod 411 has an elongated groove 431 thatpenetrates from the upper surface to a lower surface of the rod mainbody 413. This elongated groove 431 is provided near the side of the rodmain body 413 so as to extend along the side of the rod main body 412between the projecting portion 421 and the locking projection 425. Thus,a side surface portion of the rod main body 413 that extends along theelongated groove 431 is formed into a thin plate-like elastic portion433 that can be deformed elastically, and a projecting portion 435 isformed on an external surface of the elastic portion 433 that projectsslightly from the side surface of the rod main body 413.

The locking body 441 that is rested on the upper surface of the rod mainbody 413 of the switch operating rod 411 has a rod-shaped portion 445that is a rod-shaped plate body and a head portion 443 that is a platebody that is formed at one end of the rod-shaped portion 445 byexpanding the one end into a triangular shape. A width of the headportion 443 is wider than a width of the rod main body 413.

Part of this head portion 443 is made into an abutting surface 455 thatis a plane that intersects a center axis of the rod-shaped portion 445substantially at right angles. When center axes of the rod-shapedportion 445 and the rod main body 413 are made parallel to each other sothat the rod-shaped portion 445 is superposed on the rod main body 413,the abutting surface 455 and one end of the abutting projection 427 canbe brought into abutment with each other as shown in FIG. 7. As thisoccurs, the inserting shafts 475 are positioned in right positions, asseen in FIG. 18, of the first sliding hole 415 and the second slidinghole 417 on the switch operating shaft 411, whereby the switch operatingrod 411 is fixed to a left end position in its moving range.

Then, the rod-shaped portion 445 of the locking body 441 has a shafthole 447 in a middle portion thereof. The inserting shaft 475 isinserted into this shaft hole 447, whereby the locking body 441 isattached to the rod receiving shaft 471 so as to rotate about theinserting shaft 475 in a horizontal direction.

The locking body 441 has a spring mounting portion 449 at an oppositeend portion of the rod-shaped portion 445 to the end portion where thehead portion 443 is formed. As shown in FIG. 7, a tensile force producedby a spring 459 is exerted on the spring mounting portion 449, whereby aside surface of the rod-shaped portion 445 is brought into abutment withthe locking projection 425, and the rod-shaped portion 445 is superposedon the rod main body 413 so that the center axis of the rod-shapedportion 445 becomes parallel to the center axis of the rod main body413.

In addition, as this occurs, part of the head portion 443 projects tothe side of the rod main body 413, and the projecting body 457 thatprojects downwards from the lower surface of the projecting portion 421is positioned to the side of the rod main body 413 that is spacedslightly apart from the elastic portion 433 of the rod main body 413.

The locking body 441 has the operating projection 451 on an uppersurface of the head portion 443 at a portion thereof that lies on a sideopposite to the side where the projecting body 457 is provided.

The operating projection 451 has an inclined portion 453 that makes up asurface that is inclined obliquely in the direction of the shaft hole447 and is inserted into the engaging opening portion 125 of the mainbody cover portion 111.

Consequently, when the pan portion 201 is placed on the main bodyportion 110 and the pan portion 201 is rotated so that the lockingpieces 223 are positioned in the engaging opening portions 125 in such away as to be inserted under the locking pieces 223, the locking piece223 is brought into abutment with the inclined portion 453, whereby thelocking piece 223 can move the operating projection 451 towards thecenter of the main body portion 110 so that the locking body 441 rotatesabout the shaft hole 447.

Owing to this, as shown in FIG. 13, the locking body 441 rotates so thatthe center axis of the rod main body 413 and the center axis of therod-shaped portion 445 of the locking body 441 are released from theparallel state, whereby the abutting surface 455 is dislocated from theabutting projection 427, and the switch operating rod 411 can be movedin a rightward direction as seen in FIG. 13.

As this occurs, although not shown in FIG. 13, the projecting body 457is in abutment with the elastic portion 433, and when the switch knob423 is moved laterally, that is, when the switch operating rod 411 ismoved laterally, the projecting body 457 is brought into contact withthe projecting portion 435, and a sensation of clicking can be impartedto the finger tip with which the switch knob 423 is operated as a resultof resistance being generated when the projecting body 457 rives overthe projecting portion 435.

Then, by moving the switch operating rod 411 laterally, the operatingswitch 465 of the switch main body 461 is moved laterally, whereby thesupply of electric power by the power supply switch 410 is controlled tobe made or broken.

Then, when the power supply switch 410 is operated to activate thecotton candy preparing device 100 to operate, with the pan portion 201left dismounted, the switch knob 423 is prevented from being moved, thatis, the locking body 441 is prevented from being operated to switch onthe power supply switch 410. On the other hand, with the pan portion 201mounted properly, the switch knob 423 can be operated. When operatingthe power supply switch 410 to be on or off to activate or deactivatethe cotton candy preparing device 100, the power supply switch 410 canbe so operated while making the user feel that he or she has performedclearly the required operation through a sensation of clicking.

As shown in FIG. 19, in the electrical wiring of the cotton candypreparing device 100, one terminal of power supply input terminals 501that are terminals of the adapter jack 485 is connected to one terminalof the connecting jack 545 that is fixed to the first electrode ring 171and the control circuit board 175.

The second connecting ring is connected to an input terminal of aconstant voltage circuit 531 via the switch main body 461 of the powersupply switch 410. The connecting ring is connected to the otherterminal (a chassis earth terminal) of the power supply input terminals501 that are the terminals of the adaptor jack 485 via a heater switch521.

The heater switch 521 is an electromagnetic switch. A contact 525 of theheater switch 521 that makes or breaks the supply of electric power isconnected so as to be inserted between the third connecting ring and theother terminal (the chassis earth terminal) of the power supply inputterminals 501. In addition, one end of an electromagnetic module 523that controls the opening or closing of the contact 525 is connected toa constant voltage circuit 531 side of the power supply switch 410, andthe other end of the electromagnetic module 523 is connected to theother terminal (the chassis earth terminal) of the power supply inputterminals 501 via a switching transistor 527.

Then, the constant voltage circuit 531 drops a voltage of 24 volts of adirect current that is inputted from the power supply input terminals501 via the first electrode ring 171, the second electrode ring 172, andthe power supply switch 410 to a voltage of 6 volts of a direct currentto thereby output a stable control system voltage.

An output terminal of the constant voltage circuit 531 is connected toan anode terminal of a light emitting diode 537 that is disposed betweenthe power supply switch 410 that is mounted on the main body of thecotton candy preparing device 100 and the adaptor jack 485 to make up apilot lamp, an electric power input terminal of a control IC 535 thatcontrols the operation of the cotton candy preparing device 100 and anelectric power input terminal of a photocoupler 551.

This photocoupler 551 is made up of a photodiode 553, a phototransistor555 and an output transistor 557. When light outputted by the photodiode553 is reflected by an object and the reflected light is inputted intothe phototransistor 555, the photocoupler 551 passes an electric currentand outputs an H level signal from a detection signal output terminal byputting the output transistor 557 in a cutoff state. On the other hand,when the reflected light is not inputted into the phototransistor 555,the photocoupler 551 cuts off the electric current and outputs an Llevel detection signal from the detection signal output terminal byputting the output transistor 557 in an energized state.

Then, this photocoupler 551 is disposed on the upper surface of thebearing plate 167, detects a code mark 561 drawn on a lower surface ofthe gear wheel plate 373 and detects the rotation of the gear wheelplate 373, that is, the rotation of the rotary pot 260.

A cathode of the light emitting diode 537, which is made into the pilotlamp, is connected to a lamp control terminal of the control IC 535 anda detection signal output terminal of the photocoupler 551 is connectedto a detection signal input terminal of the control IC 535.

Then, a heater control terminal of the control IC 535 is connected to acontrol terminal of the switching transistor 527 so as to control theenergization of the switching transistor 527 to thereby control the onand off control of the heater switch 521.

The invention is not limited to the case where the electromagneticswitch is used as the heater switch 521 so as to be combined with theswitching transistor 527. Hence, the invention may adopt a case where afield-effect transistor is used as the heater switch 521 and the heatercurrent is directly controlled to be conducted or cut off by a controlsignal from the control IC 535.

The chassis earth terminal, which is the other terminal of the powersupply input terminals 501 of the adaptor jack 485 is connected to theheater switch 521, the power supply input terminal of the control IC 535and the photocoupler 551. The chassis earth terminal is additionallyconnected to the outer end of the connecting plug 547 via a motorcontrol transistor 541.

A control input terminal (a base terminal) of the motor controltransistor 541 is connected to the motor control terminal of the controlIC 535.

Then, as has been described above, the first lead portion 391 thatconnects together the first contact 381 and the first auxiliary contact386 that are incorporated in the pot bottom portion 310 is connected tothe first electrode plate 317 and one of the three contact detectingmembers 361, and the second lead portion 392 that connects together thesecond contact 382 and the second auxiliary contact 387 is connected tothe two remaining contact detecting members of the three contactdetecting members 361. When the pot upper portion 261 is mounted on thepot bottom portion 310, the one contact detecting member 361 and thefirst electrode plate 317 are electrically connected to the two contactdetecting member 361 via the legs 307 of the ring member 301, whereaswhen the pot upper portion 261 is removed from the pot bottom portion310, the electrical connection therebetween is cut off.

Consequently, a detecting switch 511 is formed in which the firstelectrode plate 317 and the one contact detecting member 361 make up afirst terminal 513, the ring member 301 makes up a connecting piece 517,and the two contact detecting members 361 make up a second terminal 515,and this detecting switch 511 is connected in series with the powersupply switch 410.

Owing to this configuration, even though the power supply switch 410 isoperated so that the power supply switch 410 is switched on, with thepot upper portion 261 left dismounted, no electric power is supplied tothe constant voltage circuit 531 and hence to the control IC 535,whereby the cotton candy preparing device 100 cannot be activated tooperate.

In this way, since the first electrode ring 171 to the third electrodering 173, which make up the three electrode rings, are provided on theupper surface of the bearing plate 167, heating electric power issupplied to the heaters 315 by the use of the first electrode ring 171and the third electrode ring 173, and the fact that the pot upperportion 261 is mounted on the pot base portion 310 is detected by theuse of the first electrode ring 171 and the second electrode ring 172,whereby the operation of the cotton candy preparing device 100 can becontrolled.

In the power supply switch 410, as has been described above, with thepan portion 201 left dismounted from the main body portion 110, theabutting surface 455 of the locking body 441 is kept in contact with theabutting projection 427 of the switch operating rod 411 so as to preventthe operation of the switch operating rod 411, whereby the power supplyswitch 410 can be prevented from being operated.

Consequently, the power supply switch 410 can be switched on only whenthe pan portion 201 is mounted on the main body portion 110, wherebywith the pot upper portion 261 of the rotary pot 260 mounted on the potbottom portion 310, the power supply switch 410 can be operated toactivate the cotton candy preparing device 100 to operate.

In this way, by designing the switch knob 423, which makes up the powersupply switch 410, so as not to be moved with the pan portion 201 leftdismounted, although the power supply switch 410 can be activated tooperate by operating the switch knob 423 with the pan portion 201 leftdismounted, being different from the case where the rotary pot 260 ismade not to rotate, the state where the cotton candy preparing device100 is stopped from being activated to operate can be maintained withoutmaking the user misunderstand that the device cannot be activated by anerroneous operation by the user.

Then, in activating the cotton candy preparing device 100 to operate, asshown in FIG. 20, when a power supply voltage is applied to the controlIC 535 by switching on the power switch 410, the light emitting diode537, which is formed into the pilot lamp, is illuminated first (S110).

Then, the heater switch 521 is switched on to start the heating by theheaters 315 (S120). Further, the light emitting diode 537 is turned onto flash (S125), and whether or not one minute has elapsed is determined(S130).

Then, if it is determined that one minute has elapsed, the motor controltransistor 541 is energized to start the rotation of the motor 253(S140). Then, the rotation speed of the rotary pot 260 is set at anappropriate rotation speed ranging substantially from 1500 to 200 rpm toset up a state where cotton candies can be prepared.

When the motor 253 is rotating, that is, the rotary pot 260 is rotating,the rotation speed of the rotary pot 260 is detected by an output signalof the photocoupler 551 (S150). Then, it is determined whether or notthe rotation speed of the rotary pot 260 is equal to or faster than 1000rpm (S155). Then, it is determined whether or not the power supplyswitch 410 should be switched off (S160). The rotary pot 260 is keptrotating and the heaters 315 are kept heated while repeating thedeterminations on the rotation speed of the rotary pot 260 (S155) andwhether or not the power supply switch 410 should be switched off(S160).

Then, if it is determined in step S155 that the rotation speed of therotary pot 260 is slower than 1000 rpm, the heater switch 521 isswitched off (S200) to cut off the energization of the heaters 315, andthe motor control transistor 541 is also disconnected (S210) to stop themotor 253, that is, the rotary pot 260 from rotating.

Further, it is determined whether or not the power supply switch 410should be switched off (S230) while executing a flashing control (S220)of the light emitting diode 537 in which the light emitting diode 537 iscontrolled to flash in such a way that a turn-on time becomes extremelyshorter than a turn-on time in normal flashing.

In addition to the case where the rotation speed of the rotary pot 260is kept constant within the range from 1500 to 2000 rpm, there may be acase where a short energization interruption time is provided and therotation speed of the rotary pot 260 is decelerated and acceleratedwhile keeping the rotary port 260 rotating at a rotation speed of 1000rpm or faster. By changing the rotation speed of the rotary pot 260 inthis way, when granulated sugar or sugar candy loaded in the interior ofthe rotary pot 260 becomes half melted, the granulated sugar or sugarcandy so melted can be prevented from staying at a specific location inthe interior of the rotary pot 260.

In this way, in the cotton candy preparing device 100 according to theembodiment, since the PTC heaters are used as the heaters 315, in casethe heaters 315 fail, the heating by the heaters 315 is disabled toensure the safety in an ensured fashion. In addition, the heatingtemperature is controlled to be constant automatically, this obviatingthe necessity of controlling the application voltage.

In the disassembled state where the pan portion 201 or the rotary pot260 is removed from the pot bottom portion 310, the heaters 315 areprevented from being heated or the rotary mechanism unit 250 isprevented from rotating. Therefore, the cotton candy preparing device100 is safe.

Further, the space can be defined between the cotton candy preparingdevice 100 and the table where the device is rested by the feet 153,whereby a good circulation of air can be provided in which air takeninto the main body portion 110 from the outside air intake holes 151 inthe bottom plate 143 compensates for air that escapes from the main bodyportion 110 in the form of a rising current of air heated by the heaters315 or air that is jetted from the side of the rotary pot 260 togetherwith cotton candy, thereby making it possible to prepare cotton candy ofgood quality.

The embodiment that has been described heretofore is presented as anexample of the invention, and there is no intention to limit the scopeof the invention by the embodiment. This novel embodiment can be carriedout in other various forms, and various omissions, replacements andalterations or modifications can be made thereto without departing fromthe spirit and scope of the invention. The resulting embodiments andtheir modifications are included not only in the spirit and scope of theinvention but also in the scope of inventions claimed under thefollowing claims and equivalents thereof.

What is claimed is:
 1. A cotton candy preparing device, comprising: arotary pot that can be divided into a pot upper portion and a pot bottomportion; a plurality of legs that extend downwards from the vicinity ofa circumferential edge portion of a lower end of the upper pot portionand which each include a leg end portion that expands outwards at alower end thereof; a heating plate that is provided on an upper surfaceof the pot bottom portion; and leg receiving holes that are providednear a circumferential edge portion of the upper surface of the potbottom portion and into which the legs can be inserted individually,wherein the leg receiving holes each have an inserting portion that canpermit the passage of the leg end portion and a leg stopping portionthat connects continuously to a side of the inserting portion and whosewidth to an outer circumferential direction of the rotary pot is madenarrower than the inserting portion.
 2. The cotton candy preparingdevice according to claim 1, wherein the pot bottom portion has arod-shaped engaging pin below the heating plate, and wherein theengaging pin has an engaging projecting body that is provided on a sideof the engaging pin so as to project into a triangular shape therefromand is biased by an elastic body so as cause the engaging projectingbody to project into the leg receiving hole.
 3. The cotton candypreparing device according to claim 1, wherein the plurality of legs areintegrated with a ring member that can be brought into contact with acircumferential edge of the heating plate, and the legs and the ringmember are formed of a conductive material, and wherein contactdetecting members are provided in positions on lower surfaces of the legreceiving holes of the pot bottom portion so that energization isallowed to occur between the leg end portions and the contact detectingmembers or between the contact detecting members when the leg endportions and the contact detecting members are brought into contact witheach other.
 4. The cotton candy preparing device according to claim 2,wherein the plurality of legs are integrated with a ring member that canbe brought into contact with a circumferential edge of the heatingplate, and the legs and the ring member are formed of a conductivematerial, and wherein contact detecting members are provided inpositions on lower surfaces of the leg receiving holes of the pot bottomportion so that energization is allowed to occur between the leg endportions and the contact detecting members or between the contactdetecting members when the leg end portions and the contact detectingmembers are brought into contact with each other.